System for customization or fabrication of extruded support members for facilitating access to a vehicle and related methods

ABSTRACT

Systems and methods for producing vehicle components or components for use with vehicles or in other non-vehicle applications allow an end user to select and produce at a local job site, or optionally elsewhere as desired. The system and method can allow a manufacturer or designer to send a design for a component to a consumer for the consumer to produce. The consumer can then use one of a variety of methods, such as three dimensional printing or machining, to produce the component. The consumer can produce a component from a stock data file or can customize the component before production.

FIELD OF ART

The field of the invention relates to systems and methods forcustomizing or fabrication of support members for facilitating entry andexit from a vehicle, such as adjustable steps.

BACKGROUND

Vehicles provide transportation for people and objects over distances.While many vehicles are low to the ground or have otherwise easilyaccessible passenger compartments, some do not and entry and exit maypresent a challenge. Typical examples of vehicles with more difficultaccess to passenger compartments include pickup trucks, sport-utilityvehicles, off-road vehicles, “raised” or “lifted” automobiles andothers. In these types of vehicles, the passenger compartment orcompartments may be located at a height which makes entry and exitchallenging for children, the elderly or infirm and even normalabled-body adults.

Various support member solutions are available for addressing theproblem of easy access to a passenger's compartment including the use ofrunning boards, attached step-ladders, handles to assist a passenger inpulling themselves up and others.

BRIEF DESCRIPTION OF THE DRAWINGS

These and other features and advantages of the present devices, systems,and methods will become appreciated as the same becomes betterunderstood with reference to the specification, claims and appendeddrawings wherein:

FIG. 1 is a schematic perspective view of a support device attached to avehicle, such as a pickup truck, the support device being produciblethrough the present disclosure.

FIG. 2 is a perspective view of a support device that is an exemplaryvehicle component, which can be produced through the present disclosure.

FIG. 3 shows a flowchart for an embodiment of a process for a consumerto access a design from a manufacturer and set about producing thedesign.

FIG. 4 shows a flowchart of another embodiment of the disclosed processwith additional selection features to provide relevant components to theconsumer.

FIG. 5 shows a flowchart for an embodiment where the manufacturerprogram code can be used to provision the database and generate aconsumer program code in the form of a software or application forinstallation on an electronic device used by the consumer.

FIG. 6 shows a flowchart for an embodiment where the manufacturerprogram code is utilized for generating and maintaining a database ofvehicle components as a standalone accessible database for use withseparately created consumer program code.

FIG. 7 shows a flowchart for an embodiment of a consumer program codeallowing for generally automated customization options.

FIG. 8 shows a flowchart for an embodiment allowing for additionalcustomization based on consumer dimensioning adjustments beyond changingaesthetics.

FIG. 9 shows an exemplary embodiment of a system that can be used toimplement the consumer program code.

FIG. 10 shows an exemplary embodiment of a system that can be used toimplement the manufacturer program code.

FIG. 11 shows an exemplary embodiment of a manufacturer system connectedthrough a network infrastructure to a consumer system.

DETAILED DESCRIPTION

The detailed description set forth below in connection with the appendeddrawings is intended as a description of the presently preferredembodiments of a system for customization or fabrication of supportmembers provided in accordance with aspects of the present devices,systems, and methods and is not intended to represent the only forms inwhich the present devices, systems, and methods may be constructed orutilized. The description sets forth the features and the steps forconstructing and using the embodiments of the present devices, systems,and methods in connection with the illustrated embodiments. It is to beunderstood, however, that the same or equivalent functions andstructures may be accomplished by different embodiments that are alsointended to be encompassed within the spirit and scope of the presentdisclosure. As denoted elsewhere herein, like element numbers areintended to indicate like or similar elements or features.

Currently, support members, such as running boards, attachedstep-ladders, and handles, and related accessories are all manufacturedand sold by manufacturers, or through their distributors and/orretailers, for purchase by consumers. There can be a number of reasonsfor this arrangement, including the necessity of accurate measurementsfor fitment to a vehicle and design considerations for functionality andaesthetics, maintaining of supply chains, storage consideration,industry norm, etc. Further, there is a high cost in the actualproduction of components and the required machines and tooling for theproduction. In manufacturing, economies of scale through large volumeproduction can lower the per unit cost of a good. Thus, for these areother considerations, the market place seldom allow for customization ofconsumer goods that are produced in fairly large volume.

The present disclosure generally relates to a system that enables an enduser to select, design, and/or customize to produce one or morecomponents at the location of the end user for use with themanufacturer's produced goods to result in a semi-customizable endproduct. In some examples, the user can use one of a variety of methods,such as three dimensional (3D) printing or machining, such as with alathe, a milling machine, or an CNC machine, to produce the one or morecomponents. The system can offer a number of different options anddesign choices for use with production software and an external deviceor the system can directly output production code to an attached devicefor manufacturing of the design and then shipped to the requester orpurchaser.

The system can include software for use with a computer, a downloadableapplication (App), and/or a web-browser dashboard for use online. Thesystem can include design options and templates for the end user toselect and produce. The manufacturer can have a repository or storagefor a plurality of designs, or can provide some standard designs withmore unique designs with fees. The system can allow end users to sharedesign information and design concepts for other users to enjoy.Additionally, a user may be able to customize sections of a component inorder to create a unique design for production. Still further, whileaspects of the present invention are disclosed with reference tocomponents for use with a vehicle, the invention is not limited to suchend use. For example, aspects of the present invention may be used in ahome, in an office environment, or in connection with personal goods,such as with a suitcase or backpack.

As an exemplary embodiment of components that can be produced with thesystem of the present disclosure, FIGS. 1 and 2 illustrate components ofa support device or assembly 100, which is configured for mounting to avehicle. Additional exemplary embodiments can be found in U.S.application Ser. No. 16/059,997, filed Aug. 9, 2018, and in U.S. Pat.No. 9,796,336, the contents of which are expressly incorporated hereinby reference as if set forth in full.

FIG. 1 is an exemplary perspective view of a support device or assembly100 mounted to a vehicle 10, such as to a pickup truck, a van or a sportutility vehicle (SUV), to name a few non-limiting examples. In theexemplary embodiment, the support device 100, also referred to as arunning board, is provided with a support member 102 comprising one ormore steps 104 and one or more covers or cover pieces 106 for attachingto the support device 100. The support device 100 is attached to thevehicle 10 using one or more brackets. The covers or cover pieces 106may be incorporated as decorative or ornamental pieces only, but canalso be made sufficiently sturdy for load bearing, such as for steppingon an supporting the weight of a passenger. The number of steps 104incorporated with the support device or assembly 100 can depend on thenumber of doors the support device is mounted to, such as a two doortruck or a four door SUV. Removable end caps 110 can be provided at thetwo ends of the support member 102. The end caps 110 can frictionallyengage the support member 102 and can optionally incorporate fasteners,detents, or both to more permanently secure to the support member 102,such as set screws.

FIG. 2 is a perspective view of a support device or assembly 100 inaccordance with aspects of the present invention, shown removed orspaced from a vehicle for further illustration. As shown, the supportdevice or running board 100 comprises three decorative covers 106, twosteps 104, and two end caps 110 (only one shown), one on each end of thesupport member 102. In other examples, the support device 100 can have adifferent number of decorative covers 106 and a different number ofsteps 104. For example, there can be zero decorative covers and one ormore steps 104. In another example, there can be two or more decorativecovers 106 and only one step 104. In still other examples, there can bemore than three decorative covers 106 and one or more steps 104. Thesupport member 102 of the running board 100 can have a non-circularshape cross-section. For example, the support member 102 can have acurved or arcuate upper surface 112 joined by generally flat segmentsforming a cross-section having both curved and straight segments.

FIG. 2 shows a first step 104 a in a first folded position 200 in whichthe first step part 160 is folded so that the first leg or step platform170 overlies the curved upper surface 112 of the support member 102. Thesecond step 104 b is depicted in both the first folded position 200 orrotated from the first folded position to be in the second extendedposition 202. Both the first folded position 200 and the rotated secondextended position 202 are shown to provide the viewer with a betterunderstanding that the step provided in accordance with the presentembodiment has a first step part 160 that is movable relative to asecond step part 162 to move between the first folded position 200 andthe second extended position 202. The first step part 160 is understoodto be positionable in the first folded position or the second foldedposition but not both at the same time as the single first leg 170 iseither located over the curved upper surface 112 in the first foldedposition 200 or spaced from the curved upper surface in an extendedposition 202, but not both simultaneously. The first step part 160 isalso understood to be movable relative to the support member 102 inmoving between the first position and the second position.

As shown, each step 104 comprises a first step part 160 and a secondstep part 162. As discussed in application Ser. No. 16/059,997, thesecond step part 162 can slide about a channel or groove on the supportmember 102. Once positioned to a desired location, the second step part162 can be removably fixed to the support member 102, such as with oneor more screws or fasteners.

The first step parts 160 of the two steps 104 are rotatable relative tothe support member 102 and to the second step parts 162 when the steps104, such as when the second step parts 162 of the two steps, are fixedto the support member 102 using one or more fasteners. However, prior tofixing the second step parts 162 to the support member 102, the secondstep parts 162, including the entire steps 104, are movable, such asbeing slidable, relative to the support member 102 along the length ofthe support member. Once fixed, only the first step parts 160 of thesteps are still movable.

Each first step part 160 has a first leg 170 and two side legs 172 a,172 b. As shown, the first leg 170 of each of the steps 104 has anenlarged surface area that is sized and shaped to support one or twofeet of an individual when that individual uses the step 104 to get inand out of a vehicle. The individual can step on the first leg 170 whenthe first step part 160 is in the first folded position 200 or in thesecond extended position 202. In other words, the steps 104 of thepresent invention are configured to be used in multiple positions,including when in a first folded position 200 or in a second extendedposition 202. For example, a tall person can choose to use the steps 104with the first step parts 160 in the first folded position 200 whereas arelatively shorter person can choose to use the steps with the firststep parts 160 in the second extended position 202. In either situation,the user can step onto the same first leg 170 to ingress and egress fromthe vehicle.

The first leg 170 on each step has a first surface 210 and a secondsurface 212. One or both surfaces 210, 212 can have traction features,such as bumps or projections, to increase traction between the steps andan individual's feet or shoes. The two side legs 172 a, 172 a of eachstep 104 can taper inwardly and both can have a curved body so as toform fit around the body of the elongated support member 102.

In an example, the system of the present disclosure allows forproduction of one or more components of the support device or runningboard 100 of FIG. 2 by an end user. In other examples, the system allowsfor the production of a component that is unrelated to the supportdevice, for example a customized plate for a shifter, a steering wheel,a plate, or a tag for a suitcase, to name a few non-limiting examples.

Additionally, other vehicle components can be produced through thesystem of the present disclosure. For example, aerodynamic, aesthetic,or other exterior parts, such as for body kits, can be produced throughthe present disclosure. Aerodynamic components, such as spoilers,canards, splitters, diffusers, and related mounting components, can beproduced. Exterior parts, such as components for a multi-componentsupport system, or similar mounting rack, as shown in U.S. patentapplication Ser. No. 14/866,520, published as US Publication No.2016/0090048, is the contents of which are expressly incorporated hereinby reference in their entirety, can be produced. Additionally, otheraesthetic components, such as exterior cover plates or engine valvecovers, can be produced.

FIG. 3 illustrates a flowchart for an embodiment of a process for aconsumer to access a design from a manufacturer and set about producingthe design. The process can be implemented by program code stored in acomputer readable storage medium for execution by at least one computerprocessor, such as that illustrated in FIG. 9. The program code can beconsidered as software or an application.

FIG. 3 illustrates a process comprising step S301 wherein the consumercan install a program code to a storage or memory of an electronicdevice, such as a personal computer, such as a desktop or a laptop, amobile phone, a tablet, or an electronic module or dongle. One way ofinstalling the program code can be through an application store, such asthe [GOOGLE PLAY STORE], also known as the Android Apps on Google Play,or the [APPLE APP STORE]. Alternatively, the program code may bepreinstalled for use by the consumer. Pre-installation may be especiallydesirable for implementation in a self-contained electronics module ordongle for connection to another electronic device.

Next, the program code can be executed or initialized to provide theconsumer with a graphical user interface at step S302. The execution orinitialization can be done either through selection by the consumer orautomatically. If the program code is loaded in an electronic dongle,the process can be initiated automatically upon connection of the dongleto another electronic device, or after performing a security handshakeand/or registration.

The process can provide and display a database or library of componentsat step S303. The database or library of components can be provided by amanufacturer for the consumer to select from for production or furthermodified to then produce, such as by using a 3D printer or by machining.The database can be pre-stored in the program code or accessed from aremote database via a network connection, such as the internet. Forexample, using the program on a local PC or app on a smartphone, theuser can access the remote database to select component or componentsfor printing or for further modification. As another example, theprogram can be provided through a web-browser dashboard for use online.The user can create an account and after logging into the account, theuser can be presented with a user interface with selections and optionsfor selecting and printing. The printer can be a 3D printer and canreside locally with the user or remotely at a fabricating ormanufacturing facility. If remote, the printed part can then be shippedto the requester or user. Foreseeably, a service charge may be requiredto complete the transaction.

The database can be provided in a user friendly visual format. Thedatabase can be searchable by keywords or by component categories. Thecomponent categories can group variations of a specific type ofcomponent. The various components can also be searched using othertechniques, such graphically, by pull tabs, or combinations of differentsearchable techniques.

In some embodiments, the program code may only display particular orsub-set of components from the database. In such a case, there may beparticular components that the manufacturer would like to have releasedto the consumer. This can be the basis for a subscription-based serviceto access components from the database, as an example.

In some embodiments, the particular components or subset of componentsare displayed in connection with monthly promotions. Such a set up canbe beneficial in urging consumers to continually check themanufacturer's latest offerings.

From the database of components, the consumer can select a specificcomponent for production or can select more than one component forproduction. From the selection of the component for production, theprogram code can then generate an output suitable for instructing aproduction machine to execute at step S304. Such a production machinecan be a 3D printer, lathe, mill, extruder, or other computerprogrammable devices, such as CNC machines. The output can be a datafile that can either be transmitted directly to the production machineor transferred to the production machine. In addition to producing thecomponent, the output may be for production of an inverse form or mold.Production of such a form or mold would allow for production of thedesired component through additional steps using the form or mold, suchas with composite lay ups or injection molding techniques. As anexample, the system allows the end caps 110 of FIG. 2 to be produced tothen attach to the support member 102. The end caps 110 can be producedusing a user selected color or colors, a desired contour, desiredsurface features, such as bumps, grooves, graphics, etc. In otherexamples, the system allows the user to print inserts or plates forplacement into the recessed space of each of the two end caps 110. Theinserts or plates can include user selected design, text, graphics, etc.The decorative cover 106 (FIG. 2), if selected to be non-load bearing,can also be printed with custom features, such as colors, surfacefeatures, bumps, textures, etc.

In embodiments, the program code can transmit the output data file to aconnected production machine at step S305, such as a 3D printer. The 3Dprinter can use any of OBJ, STL, VRML, X3G, PLY, and FBX data files orother current or future file format for 3D printing. Similarly, thelathe, mill, or extruder can use suitable data files for production fromknown computer aided manufacturing (CAM) and computer numerical control(CNC).

In some embodiments, the consumer can output the production instructionsto a personally owned or attached production machine. Embodiments areenvisioned for direct consumer usage with 3D printers. Also, by allowingthe output of data files to other production machines, such as to alathe or milling machine, the system can allow for different productiontime requirements and component materials. For example, some consumersmay prefer to have their component manufactured from a metal billet foraesthetic, strength, and durability reasons while others may be drivenby aesthetic reason only.

Additionally, embodiments can be used for larger scale production suchas by a licensee of the manufacturer. By providing direct outputtingfrom the software to production machines, such as to an extruder, 3Dprinter, and/or metal or plastic injection machine, a manufacturer canprovide a licensee with a path or option for manufacturing the parts orcomponents without divulging trade secret information.

In the case of the connected production machine, the program code canalso continually check the production status at step S306. Uponcompletion of production of a component by the production machine, theprogram code can generate a notification or alarm for the consumer toindicate that the component is completed at step S307.

FIG. 4 illustrates a flowchart or process for producing componentssimilar to that of FIG. 3 with additional selection features. Theprocess can be implemented by program code stored in a computer readablestorage medium for execution by at least one computer processor, such asthat illustrated in FIG. 9. The program code can be considered asoftware or an application.

FIG. 4 illustrates a process wherein the consumer can install theprogram code to storage of an electronic device, such as a personalcomputer, a mobile phone, a tablet, or an electronic module or dongle,at step S401. Alternatively, the program code may be preinstalled foruse by the consumer. Pre-installation may be especially desirable forimplementation in a self-contained electronic module or dongle forconnection to another electronic device.

Next, the program code can be executed or initialized to provide theconsumer with a graphical user interface for the process. The executionor initialization can be done either through selection by the consumeror automatically. If the program code is loaded in an electronic dongle,the process can be initiated automatically upon connection to anotherelectronic device.

The process can provide a configuration setup at step S402 wherein theconsumer can specify the vehicle that they would like to producecomponents for or can be provided with a limited list of components orparts within an assembly, such as the support device 100, for producing.For example, the user can be presented with options for printing adecorative cover 106 or an end cover 100. For other accessories, theuser can be presented with other component options for printing.

The process can provide and display a database or library of componentsthat is tailored for the specified vehicle at step S403, which has beenprovided by a manufacturer, for the consumer to select for production.The database can be pre-stored in the program code or accessed from aremote database via a network connection, such as the internet.

With the configuration setup step S402, it is possible to have asignificantly larger database for many different vehicles and the listof components can be tailored for the consumer's consideration.Furthermore, the database can be provided in a user friendly visualformat. The database can be searchable by keywords or by componentcategories. The component categories can group variations of a specifictype of component.

In some embodiments, the program code may only display particular orsubset of components from the database. In such a case, there may beparticular components that the manufacturer would like to have releasedto the consumer, with conditions. This can be the basis for asubscription-based service to access components from the database.

In some embodiments, the particular components that are only selectivelymade available can be envisioned for usage in monthly promotions. Such aset up can be beneficial in urging consumers to continually check themanufacturer's latest offerings.

From the database of components, the consumer can select a specificcomponent for production. In some examples, the user can be providedwith a graphical display of an assembly or device with only parts orcomponents within the assembly to be producible by a user enabled forselection. From the selection of the component for production, theprogram code can then generate an output suitable for instructing aproduction machine at step S404. Such a production machine can be a 3Dprinter, lathe, mill, extruder, or other computer program machines, suchas CNC machines. The output can be a data file that can either betransmitted directly to the production machine or transferred to theproduction machine. In addition to producing the component, the outputmay be for production of an inverse form or mold. Production of such aform or mold would allow for production of the desired component throughadditional steps using the form or mold, such as with composite lay upsor injection molding techniques.

In embodiments, the program code can transmit the output data file to aconnected production machine at step S405. The 3D printer can use any ofOBJ, STL, VRML, X3G, PLY, and FBX data files or other current or futurefile format for 3D printing. Similarly, the lathe, mill, or extruder canuse suitable data files for production from known computer aidedmanufacturing (CAM) and computer numerical control (CNC).

In some embodiments, the consumer can output the production instructionsto a personally owned or attached production machine. Embodiments areenvisioned for directing the data file by a consumer to a connected 3Dprinter. Also, by allowing output of data files to other productionmachines, such as lathes and mills, the system can allow for differentproduction time requirements and component materials. For example, someconsumers may prefer to have their component manufactured from metalbillet for aesthetic reasons.

Additionally, embodiments can be used for larger scale production suchas by a licensee of the manufacturer. By providing direct outputtingfrom the software to the production machine, such as an extruder, thesystem allows a manufacturer to enable a licensee with means forpracticing the device or apparatus without having to directly transfertrade secret information to the licensee.

In the case of the connected production machine, the program code canalso continually check the production status at step S406. Uponcompletion of production of the component by the production machine, theprogram code can generate a notification or alarm for the consumer toindicate that the component is completed at step S407.

FIGS. 5 and 6 illustrate flowcharts for embodiments involving amanufacturer providing a database having designs for the consumer toaccess and set about producing the design, such as with a productionmachine. The process of FIG. 5 can be understood as corresponding to theconsumer implemented program code of FIGS. 3, 4, 7, and 8. Themanufacturer's process can be implemented by manufacturer program codestored in a computer readable storage medium for execution by at leastone computer processor, such as that illustrated in FIG. 10. The programcode can be considered a software, an application, or a web pagedashboard.

The manufacturer program code can be used to provision the database andgenerate a consumer program code in the form of a software orapplication for installation on an electronic device used by theconsumer, such as the embodiments of FIGS. 3, 4, 7, and 8.Alternatively, the manufacturer program code can be used to provisionthe database as a standalone accessible database for use with aseparately created consumer program code.

FIG. 5 illustrates a flowchart for an embodiment where the manufacturerprogram code can be used to provision the database and generate aconsumer program code in the form of a software or application forinstallation on an electronic device used by the consumer. In such acase, the database of components can be stored locally on the consumerelectronic device as part of the consumer program code.

The process can allow for uploading data for component or components tobe produced to a computer readable storage at step S501. The data forthe one or more components, which can be for a vehicle or for otherdevices, can then be accessible by the manufacturer program code whencreating the consumer program code such that the data for the componentsto be produced is incorporated into the consumer program code.

In embodiments, the data for the individual components stored in thedatabase can include data or metadata to identify specific vehicles thatthe component will fit with. This can aid in categorization oridentification of relevant components for the consumer, as in stepsS304, S403, and S404 of the embodiments of FIGS. 3 and 4.

In some embodiments, to accommodate customizability by the consumer asshown in the embodiments of FIGS. 7 and 8, specific features of certaincomponents can be identified as customizable. The data for theindividual components stored in the database can include identificationof specific dimensions or areas of the components that can be altered orcustomizable. Embodiments of processes as to how a consumer cancustomize components are described further below with reference to FIGS.7 and 8. Additionally, data of variations of the specific feature thatis customizable can be stored in the database separately from vehiclecomponent data. Alternatively, data of variations of the specificfeature can be drawn from the plurality of vehicle components with asimilar specific feature identified as customizable. The indication ofsimilarity can be saved in the data or metadata of the component.

Optionally, the process can include time configuration of whenindividual components should be made available to the consumer at stepS502. In such a case, only identified components can be shown by theconsumer program code for production. This feature can also allow forin-house manufacturing testing of a component from the database beforegeneral release.

Next, the process can include compiling program code at step S503 toprovide software or an application to provide the database and timeconfiguration in consumer program code such that the consumer hasconsumer program code according to embodiments shown in FIGS. 3, 4, 7,and 8.

After creation of the consumer program code at step S503, the processcan include either distribution to consumers via downloading from theCloud by the consumer at step S504 or an in-software or in-applicationinstallation option at step S505. The upload can be to a website or anapplication store, such as the [GOOGLE PLAY STORE] or the [APPLE APPSTORE]. With the in-software or in-application installation option atstep S505, a link can be provided through either existingsoftware/application as an update or through a tangentially relatedsoftware/application from the manufacturer.

In this way, the consumer program code can operate locally withoutconnection to an external network, as the data for the components isincluded with the consumer program code.

Alternatively, older styles of distribution including sending theconsumer program code to physical media printing, such as to a compactdisc (CD), can also be envisioned.

FIG. 6 illustrates a flowchart for an embodiment where the manufacturerprogram code is utilized for generating and maintaining a database ofvehicle components or components for use with a vehicle as a standaloneaccessible database for use with separately created consumer programcode. In other examples, the manufacturer can have a database containingcomponents from non-automobile type components, such as components for asuitcase, for a backpack, for shoes, for a computer, for householdgoods, for consumer goods, such as a smartphone cover, etc. Thesenon-automobile type components can be incorporated within a system asdiscussed herein for vehicle components or components for use with avehicle.

In the present embodiment, the database of vehicle components is storedon a network accessible storage, such that consumer program code forconsumer electronic devices can access the network accessible databaseas needed. Such a network could include the internet or an intranetusing a smartphone, a tablet, or a computer.

The process can allow for uploading data for vehicle components tocomputer readable storage at step S601 for the formation of thedatabase.

In embodiments, the data for the individual components stored in thedatabase can include data or metadata to identify specific vehicles thatthe component will fit with. This can aid in categorization oridentification of relevant components for the consumer, as in stepsS304, S403, and S404 of the embodiments of FIGS. 3 and 4.

In some embodiments, to accommodate customizability by the consumer asshown in the embodiments of FIGS. 7 and 8, specific features of thecomponent can be identified as customizable. The data for the individualcomponents stored in the database can include identification of specificdimensions or areas of the components that can be altered. Embodimentsof processes as to how a consumer can customize components are describedfurther below with respect to FIGS. 7 and 8. Additionally, data ofvariations of the specific feature that is customizable can be stored inthe database separately from the vehicle component data. Alternatively,data of variations of the specific feature can be drawn from theplurality of vehicle components with a similar specific featureidentified as customizable. The indication of similarity can be saved inthe data or metadata of the component.

Optionally, the process can include time configuration of whenindividual components should be made available to the consumer at stepS602. In such a case, only identified components can be shown by theconsumer program code for production.

After initial uploading of the vehicle components, the manufacturerprogram code can also allow for updating or modification at step S603 ofindividual vehicle components. For example, the manufacturer programcode can allow for identification of specific features of the vehiclecomponent for customization in what was initially uploaded as anon-customizable component. Additional disclosure of customizablefeatures is provided below with respect to FIGS. 7 and 8.

FIGS. 7 and 8 provide flowcharts for embodiments of processes forconsumer program code that can allow for customization of components. Inallowing the consumer to utilize their own tooling to produce thecomponents, the system provided by the manufacturer can allow forcustomization of features in ways that would not be possible withtraditional mass production.

FIG. 7 illustrates a flowchart for an embodiment of a consumer programcode allowing for generally automated customization options. Forexample, this can include replacement of aesthetic designs or features,the placement of text or logos on surfaces of the component, and the useof different colors and color combinations to make the component and thecustomized features. Such customization can be done simply without needto redesign the vehicle component.

The consumer program code can access and display a database or libraryof components at step S701, which has been provided by a manufacturer,for the consumer to select for production. The database can bepre-stored in the program code or accessed from a remote database via anetwork connection, such as the internet.

The database can be provided in a user friendly visual format. Thedatabase can be searchable by keywords, by component categories, orgraphically by pictures or drawings. The component categories can groupvariations of a specific type of component.

In some embodiments, the program code may only display particularcomponents from the database. In such a case, there may be particularcomponents that the manufacturer would like to have released to theconsumer. As shown in FIG. 4, this can include additional selections bythe consumer as to specific vehicles that the consumer is interested incomponents for. The process can provide a configuration setup at stepS702 wherein the consumer can specify the vehicle that they would liketo produce components for use with. The process can provide and displaya database or library of components that is tailored for the specifiedvehicle S703, which has been provided by a manufacturer, for theconsumer to select for production. From the database of components, theconsumer can select a specific component for customization prior toproduction.

After selection of the component, the process can include providing auser interface for customization of the component at step S704. Specificareas that identified as customizable may also have a variety ofaesthetic variations available for selection. For example, in the caseof a step 104 or a decorative cover 106 (FIG. 2), an aesthetic patternprovided on the step 104 or decorative cover 106 can be altered. Theconsumer program code can provide for a listing of alternative aestheticpatterns for the specific feature. Examples of this may include a visuallist showing the different variations that can be used. In someexamples, the system can allow multiple components to be accessed,customized, and produced.

Additionally, relatively simple customization such as the addition oftext or logos on a surface of a component can be achieved. By allowing aconsumer to directly include text or a logo into or onto the component,the end result is a more professional, handcrafted, uniqueness, orluxury feel to the component rather than mass produced.

Following customization, the consumer program code can then generate anoutput suitable for instructing a production machine at step S705. Sucha production machine can be a 3D printer, lathe, mill, extruder, orother devices. The output can be a data file that can either betransmitted directly to the production machine or transferred to theproduction machine. In addition to producing the component, the outputmay be for production of an inverse form or mold. Production of such aform or mold would allow for production of the desired component throughadditional steps using the form or mold, such as with composite lay upsor injection molding techniques.

In embodiments, the program code can transmit the output data file to aconnected production machine at step S706. The 3D printer can use any ofOBJ, STL, VRML, X3G, PLY, and FB X data files or other current or futurefile format for 3D printing. Similarly, the lathe, mill, or extruder canuse suitable data files for production from known computer aidedmanufacturing (CAM) and computer numerical control (CNC).

In some embodiments, the consumer can output the production instructionsto a personally owned or attached production machine. Embodiments areenvisioned where the consumer can send the data file directly to a local3D printer for immediate production and use. Also, by allowingoutputting to other production machines, such as lathes and mills, thesystem can allow for different production time requirements andcomponent materials. For example, some consumers may prefer to havetheir component manufactured from metal billet for aesthetic reasons.

In the case of the connected production machine, the program code canalso continually check the production status at step S707. Uponcompletion of production of the component by the production machine, theprogram code can generate a notification or alarm for the consumer toindicate that the component is completed at step S708.

FIG. 8 illustrates a flowchart for an embodiment for customizationsimilar to that of FIG. 7, but allows for additional customization basedon consumer dimensioning adjustments beyond changing aesthetic features.

The flowchart of FIG. 8 is similar to the embodiment of FIG. 7 and hascorresponding steps with some changes.

The consumer program code can access and display a database or libraryof components at step S801, which has been provided by a manufacturer,for the consumer to select for production.

In some embodiments, the program code may only display particularcomponents from the database. In such a case, there may be particularcomponents that the manufacturer would like to have released to theconsumer while withholding some others. As shown in FIG. 7, this caninclude additional selection by the consumer as to specific vehiclesthat the consumer is interested in components for. The process canprovide a configuration setup at step S802 wherein the consumer canspecify the vehicle that they would like to produce components for. Theprocess can provide and display a database or library of components thatis tailored for the specified vehicle at step S803, which has beenprovided by a manufacturer, for the consumer to select for production.From the database of components, the consumer can select a specificcomponent for customization prior to production. The consumer can repeatthe steps for additional components. In some instances, the systemallows multiple components to be customized at the same time.

After selection of the component for customization in FIG. 8, theprocess can include customization at step S804 a. As with the embodimentof FIG. 7, specific areas that identified as customizable may also havea variety of aesthetic variations available for selection. Additionally,relatively simple customization such as the additional of text or logoson a surface of a component can be achieved.

Beyond the simplistic customization, the embodiment can allowcustomization of dimensions of the component at step S804 b. In thiscase, the consumer can be provided with the ability to customizedimensions such as length or height of the component. As an example,this has benefits by accommodating varying vehicle dimensions due todifferent models or due to personal aesthetic preference or taste. Thecustomization can be done through numerical entries of desireddimensions or through a visual interface showing the component.

Following the step that allows for adjustments in dimensions, productionof the component can be achieved similarly to the embodiment of FIG. 7.

Following customization, the consumer program code can then generate anoutput suitable for instructing a production machine at step S805. Sucha production machine can be a 3D printer, lathe, mill, extruder, orother. The output can be a data file that can either be transmitteddirectly to the production machine or transferred to the productionmachine. In addition to producing the component, the output may be forproduction of an inverse form or mold. Production of such a form or moldwould allow for production of the desired component through additionalsteps using the form or mold, such as with composite lay ups orinjection molding techniques.

In embodiments, the program code can transmit the output data file to aconnected production machine at step S806. The 3D printer can use any ofOBJ, STL, VRML, X3G, PLY, and FBX data files or other current or futurefile format for 3D printing. Similarly, the lathe, mill, or extruder canuse suitable data files for production from known computer aidedmanufacturing (CAM) and computer numerical control (CNC).

In some embodiments, the consumer can output the production instructionsto a personally owned or attached production machine. Embodiments areenvisioned where the consumer can send the data file directly to a local3D printer for immediate production and use. Also, by allowing output toother production machines, such as lathes and mills, the system canallow for different production time requirements and componentmaterials. For example, some consumers may prefer to have theircomponent manufactured from metal billet for aesthetic reasons.

In the case of the connected production machine, the program code canalso continually check the production status at step S807. Uponcompletion of production of the component by the production machine, theprogram code can generate a notification or alarm for the consumer toindicate that the component is completed at step S808.

FIG. 9 illustrates an exemplary embodiment of a system that can be usedto implement the consumer program code of FIGS. 3, 4, 7, and 8. Thesystem can include a computer readable storage medium 901, a processor902, and an input/output module 904. The input/output module 904 caninclude network communication ports or physical media interfacing forinterfacing the generated output for production of the vehicle componentwith the production machine. These elements can form the basis of anelectronic device to implement the consumer program code. For example,these elements could be part of an electronic dongle. Additionally, thesystem can include a human interface device 903 and a display 905 forinterfacing by the consumer. Furthermore, a production machine 906 canbe attached to the system. In some embodiments, the computer readablestorage medium 901, the processor 902, and the input/output module 904can be integral with the production machine 906.

FIG. 10 illustrates an exemplary embodiment of a system that can be usedto implement the manufacturer program code of FIGS. 5 and 6. The systemcan include a computer readable storage medium 1001, a processor 1002,and an input/output module 1004. The input/output module 1004 caninclude network communication ports or physical media interfacing. Theseelements can form the basis of an electronic device to implement themanufacturer program code. Additionally, the system can include a humaninterface device 1003 and a display 1005 for interfacing by theconsumer.

FIG. 11 is an exemplary embodiment of a manufacturer system 1110connected through a network infrastructure 1130 to a consumer system1150. The manufacturer system 1110 can include the components necessaryto implement the manufacturer program code, such as that seen in FIG.10. The manufacturer system 1110 can include at least one computer orworkstation 1112 having the components of the computer readable storagemedium 1001, the processor 1002, and the input/output module 1004described in the embodiment of FIG. 10. In some cases with largercompanies, it is likely that the manufacturer will have multiplecomputers or workstations 1114 in the manufacturer system, any of whichcan implement the manufacturer program code. In embodiments, thecomputers will be connected to a router 1118 and a modem 1120 forconnection to each other and to the network infrastructure 1130 outsideof the manufacturer system 1110. Alternatively, the manufacturer system1110 can be a remote cloud network with virtual machine provisioning forthe manufacturer to interface with the cloud network.

The network infrastructure 1130 can be the internet or an intranetinfrastructure. The manufacturer system 1110 can connect to the networkinfrastructure 1130 through the modem 1120 and an internet serviceprovider.

The consumer system 1150 can include the components necessary toimplement the consumer program code, such as that seen in FIG. 9. Theconsumer system 1150 can include at least one computer or workstation1152 having the components of the computer readable storage medium 901,the processor 902, the input/output module 904, and the productionmachine 906 described in the embodiment of FIG. 9. In embodiments, thecomputer 1152 will be connected to a router 1158 and a modem 1150 forconnection to the network infrastructure 1130 outside of themanufacturer system 1110. Alternatively, the consumer system 1150 can bea remote cloud network with virtual machine provisioning for theconsumer to interface with the cloud network.

Systems and methods of making the vehicle components or components foruse with a vehicle or for other applications are understood to be withinthe scope of the present disclosure.

Although limited embodiments of systems and processes for producingsupport devices, assemblies, their components, and various vehiclecomponents have been specifically described and illustrated herein, manymodifications and variations will be apparent to those skilled in theart. For example, the processes may incorporate multi-machine productiontechniques, hand-finishing of components, and alternative productionmachines, etc. Furthermore, it is understood and contemplated thatfeatures specifically discussed for one embodiment may be adopted forinclusion with another embodiment, provided the functions arecompatible. Accordingly, it is to be understood that the systems andprocesses for producing support devices, assemblies, and theircomponents constructed according to principles of the disclosed device,system, and method may be embodied other than as specifically describedherein. The disclosure is also defined in the following claims.

What is claimed is:
 1. A method for production of vehicle componentsdirected by a consumer interacting with a computer, comprising:retrieving a listing of vehicle components from a vehicle componentdatabase, components on the listing of vehicle components are attachedto a produced good; displaying a subset of the listing of vehiclecomponents to the consumer based on a time period defined by amanufacturer associated with the vehicle components or a consumersubscription; selecting a vehicle component that couples to the producedgood from the vehicle component database based on a selection input fromthe consumer from the subset of vehicle components; following receipt ofthe selection input from the consumer, the computer generating an outputdata file from data for the vehicle component from the vehicle componentdatabase, the output data file being configured to be readable by aproduction machine and to instruct the production machine to produce thevehicle component; transmitting the output data file to the productionmachine to instruct the production machine to produce the vehiclecomponent; and wherein the vehicle component produced by the productionmachine is attachable to the produced good for the vehicle.
 2. Themethod of claim 1, wherein the production machine comprises one of a 3Dprinter, a mill, a lathe, and an extruder.
 3. The method of claim 2,wherein the vehicle component database is remotely located from theproduction machine and is accessed through a network.
 4. The method ofclaim 2, further comprising: identifying a particular produced good inorder to generate a listing of vehicle components relevant to theparticular produced good from the vehicle component database.
 5. Themethod of claim 2, further comprising: receiving a modification inputfrom the consumer; and modifying the vehicle component selected from thevehicle component database in accordance with the modification inputbefore generating the output data file.
 6. The method of claim 5,wherein the modifying comprises changing a design on the selectedvehicle component.
 7. The method of claim 5, wherein the modifyingcomprises changing a dimension of the selected vehicle component.
 8. Themethod of claim 5, wherein the modifying comprises adding text or agraphic logo to a surface of the selected vehicle component.
 9. Themethod of claim 2, further comprising: checking a status of productionof the vehicle component by the production machine; and displaying analert to the consumer upon completion of production by the productionmachine.
 10. The method of claim 1, wherein the vehicle componentcomprises an end cap that couples to the produced good.
 11. The methodof claim 1, wherein retrieving the listing from the vehicle componentdatabase comprises retrieving the listing from a remote vehiclecomponent database located with a manufacturer and wherein providing thevehicle component to the consumer comprises instructing the productionmachine located with the consumer to produce the vehicle component. 12.The method of claim 1, further comprising providing the vehicle thevehicle component produced by the production machine to the consumer forcoupling the vehicle component to the produced good mounted to thevehicle for moving with the vehicle.
 13. A system for production ofvehicle components for a produced good linked to a vehicle comprising: aproduction machine; a processor; a non-transitory computer readablestorage medium having a program code executable by the processor, theprogram code configured to: retrieve a list of vehicle components thatcouple to an assembly comprising the produced good from a vehiclecomponent database; display a subset of the list of vehicle componentsto the consumer based on a time period defined by a manufacturerassociated with the vehicle components or a consumer subscription;receive a selection input from the subset of the list of vehiclecomponents from a user; select a vehicle component from the vehiclecomponent database based on the selection input; and generate an outputdata file from data for the vehicle component selected from the vehiclecomponent database, the output data file configured to be readable bythe production machine and to instruct the production machine to producethe vehicle component for coupling to the assembly of the produced good;and transmit the output data file to the production machine to instructthe production machine to produce the vehicle component for coupling tothe assembly of the produced good.
 14. The system of claim 13, whereinthe production machine comprises one of a 3D printer, a mill, a lathe,and an extruder.
 15. The system of claim 14, wherein the vehiclecomponent database is remotely located from the production machine andis accessed through a network.
 16. The system of claim 14, wherein theprogram code further comprises: identifying a particular produced goodin order to generate a listing of vehicle components relevant to theparticular produced good from the vehicle component database.
 17. Thesystem of claim 14, wherein the program code is further configured to:receive a modification input from the user; and modify the vehiclecomponent selected from the vehicle component database based on themodification input before generating the output data file.
 18. Thesystem of claim 17, wherein the modifying comprises changing a design onthe selected vehicle component.
 19. The system of claim 17, wherein themodifying comprises changing a dimension of the selected vehiclecomponent.
 20. The system of claim 17, wherein the modifying comprisesadding text or a graphic logo to a surface of the selected vehiclecomponent.
 21. The system of claim 13, wherein the program code furthercomprises: checking a status of production of the vehicle component bythe production machine; and displaying an alert upon completion ofproduction by the production machine.
 22. The system of claim 13,further comprising: an input/output module configured to communicateelectronically with the production machine.
 23. The system of claim 17,wherein the program code is further configured to identify a modifiablearea of the vehicle component and a non-modifiable area of the vehiclecomponent, and modifying the vehicle component comprises changing themodifiable area while keeping the non-modifiable area intact.